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引用次数: 172
摘要
f1 - atp酶是由单个蛋白质分子组成的旋转马达。其旋转是由ATP水解获得的自由能驱动的。在体内,另一个马达,Fo,可能使F1的马达向相反的方向旋转,也逆转了F1中的化学反应,使其合成ATP。在这里,我们试图回答两个相关的问题,ATP水解获得的自由能如何转化为旋转的机械功,以及对F1所做的机械功如何转化为产生ATP的自由能?在总结了F1旋转的单分子观察后,我们引入了一个玩具模型,并讨论了它的自由能图,以可能回答上述问题。我们还讨论了分子马达的一般效率。
Rotation of F1-ATPase: how an ATP-driven molecular machine may work.
F1-ATPase is a rotary motor made of a single protein molecule. Its rotation is driven by free energy obtained by ATP hydrolysis. In vivo, another motor, Fo, presumably rotates the F1 motor in the reverse direction, reversing also the chemical reaction in F1 to let it synthesize ATP. Here we attempt to answer two related questions, How is free energy obtained by ATP hydrolysis converted to the mechanical work of rotation, and how is mechanical work done on F1 converted to free energy to produce ATP? After summarizing single-molecule observations of F1 rotation, we introduce a toy model and discuss its free-energy diagrams to possibly answer the above questions. We also discuss the efficiency of molecular motors in general.
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